Cascade stacking and cascade electrofocusing: their interconversion and fundamental unity.

The composition of a stack [an isotachophoresis (ITP) system] containing multiple trailing buffer constituents (“cascade stack”) was computed using a modification of the program of Routs. On electrophoresis, such a buffer mixture gave rise to multiple moving boundaries in which either buffer constituents or proteins could be stacked. Buffer zones within the stack served as “spacers.” The cascade stack exhibits a pH gradient, sharp zone boundaries, and constant zone width irrespective of the duration of electrophoresis, just as in the case of a stack comprising a single leading and trailing constituent. The pH gradient, sharp zone boundaries, and the sequential order of protein zones were maintained when the cascade stack was transposed between strongly acidic and basic electrolytes. Such a transposed isotachophoretic gel functioned as an electrofocusing system, indistinguishable from electrofocusing gels made in either buffers (buffer electrofocusing, or BEF) or Ampholine (isoelectric focusing, or IF). In the converse experiment, a cascade electrofocusing gel, formed in the same buffer mixture used to form a cascade stack, was subjected to electrofocusing until the steady-state was attained and then it was transposed between the appropriate upper and lower buffers of the corresponding cascade stacking system. Such transposition gave rise to moving zones with the typically sharp boundaries of a stack, a transient state pH gradient, and an order of protein zones within the cascade stack identical to the cascade electrofocusing system. These studies indicate the essential physical-chemical identity between these two types of electrophoretic systems and indicate the need for continued development of a unified theory for isoelectric focusing and steady-state stacking (isotachophoresis).     

Synergism of capillary isotachophoresis and capillary zone electrophoresis

The combination of capillary isotachophoresis and capillary zone electrophoresis may enhance greatly the performance of analytical capillary electrophoresis with respect to both separation power and the concentration sensitivity. The concentrating effects and the separation power of isotachophoresis allow the analysis of diluted samples and the elimination of interferences due to bulk components. The separation process of zone electrophoresis enables one to resolve the stack of trace analytes and detect the resulting individual zones with high sensitivity. The transition of isotachophoresis into zone electrophoresis plays the key role in the overall performance of this hyphenated technique. This article describes the dynamics of the conversion of isotachophoresis into zone electrophoretic mode and shows that the key role is played by the segments of the leading and terminating zones from the isotachophoretic stage. The magnitude of these segments directly effects the detection time as well as the separation width of the peaks of analytes. It is shown that these effects are also important in the analyses by capillary zone electrophoresis where isotachophoresis is induced by the sample itself. Finally, the paper presents a list of recommended, user-friendly, electrolyte systems which enable one to simply predict the performance of the combination isotachophoresis-zone electrophoresis.     

Aggregation of ampholine on heparin and other acidic polysaccharides in isoelectric focusing.

The mechanism of complexation of pI range 3.5--5 Ampholine to heparin in isoelectric focusing has been explored by the dye-binding technique at different pH values in solution. There is no significant interaction between heparin and Ampholine at pH 6.7. Weak, or selective, binding occurs at pH 5.1, and very strong interaction at pH 3.5. In the latter system, the Ampholine components appear to behave as polycations due to their ordered sequence of positive charges, each two methylene groups apart, which favors a strong binding to polyanions. In addition, there appear to be variable stoichiometries for the strong binding between heparin and Ampholine, depending on their relative amounts. It is proposed that at a low ratio of heparin to Ampholine (Ampholine excess), aggregation is perpendicular to the heparin chain, with the end ammonium charge of each Ampholine molecule neutralizing one negative charge along the heparin molecule; at higher ratios (heparin excess), the bound Ampholine segment is aligned parallel to the heparin molecule, so that on the average one Ampholine component neutralizes approx. three negative charges. The banding of heparin in isoelectric focusing in the pH range 3.0--4.5 can be explained by aggregation of the various components on heparin in amounts dependent upon the net charge on the Ampholine species at the given pH, and upon the changing stoichiometries as a function of the variation in ratio of heparin to Ampholine along the pH gradient. Binding of Ampholine to polygalacturonate was also demonstrated in excess Ampholine in a pH range dependent on the degree of protonation of the carboxyl groups of this acidic polysaccharide as well as on the net positive charge of the Ampholine. The aggregation seen at pH 4.2--4.5 led to the prediction and subsequent demonstration that polygalacturonate would also exhibit binding upon isoelectric focusing. This supports the hypothesis that aggregation of Ampholine on polyanions having sufficient charge density is a general phenomenon which can lead to spurious banding of certain polymers at appropriate pH ranges in isoelectric focusing. On the basis of their behavior in isoelectric focusing at pH 3.0--4.5, strength of aggregation of the polyanions studied appears to be heparin A = heparin B greather than polyglutamate greater than carboxyl-reduced heparin B greater than polygalacturonic acid.     

Isotachophoresis of nucleic acid constituents

Determination methods for purine and pyrimidine bases, nucleosides, nucleotides and related compounds using analytical capillary isotachophoresis are reviewed. First, the isotachophoretic characterization of these compounds, as well as methods for sample preparation prior to analysis, and the different ways of detecting unknown substances in complex biological systems are described. Then applications of isotachophoretic analysis in medical diagnosis and biomedical research are reviewed. In particular, the analysis of purines, pyrimidines, nucleosides and related compounds in blood and serum for the diagnosis and treatment of inherited diseases and cancer is described. Selected applications of nucleotide analysis in biomedical research using different tissue extracts are also reviewed, and some examples of nucleotide-dependent enzymic reactions, which were performed by means of analytical isotachophoresis, are presented.     

Nonisoelectric focusing in buffers.

Stable pH gradients were formed and focusing of proteins was carried out in polyacrylamide gels containing mixtures of simple, amphoteric buffers, replacing the Ampholine hitherto used in isoelectric focusing (IF). Stable pH gradients can also be formed between acid anolyte and basic catholyte if Ampholine is replaced by nonamphoteric buffers. The fact that focusing can be carried out with nonampholytes shows that focusing in this case is, and in all other cases may be, nonisoelectric. It is postulated that the pH gradient in IF forms by steady-state stacking (isotachophoresis) and forms within the stack. In distinction to ordinary steady-state stacking, however, the stack remains confined within the gel (or density gradient) since the strong acid and base in the electrolyte reservoirs bar by deprotonation or electrostatic repulsion migration into the electrode chambers.     

Amino acid spacing in isotachophoresi; on polyacrylamide gel: a critical evaluation.

Isotachophoresis of colored model proteins was carried out on polyacrylamide gel, using the stack of a multiphasic buffer system computed on the basis of the Jovin theory and operative at pH 10.4. The stack was elongated by milligram loads of various amino acids per analytical gel. The extent of the stack was determined by chemical localization of the leading and trailing constituents. The isotachophoretic nature of the stack was ascertained by determining the positions of all protein specles under study as intermediate between the leading and trailing constituents. The shallow pH gradient across the extended stack was measured. Spacing of proteins in isotachophoresis is restricted, with regard to constituent multiplicity and constituent load, by the practical limitations of electrophoresis time and gel length. Therefore, spacing by a small number of constituents at relatively low loads was attempted. Amino acids were chosen as spacers because they can be selected conveniently, in radioactively labeled form, for the specific separation between pairs of proteins with particular mobilities. In the particular buffer system used, lysine, histidine, serine, and threonine were found to be effective spacers between bovine serum albumin (BSA) and hemoglobins, while no amino acids effectively spaced between hemoglobins A and S. It is concluded that specific spacing in isotachophoresis on polyacrylamide gel (ITPPA) can be useful in improving resolution. However, in practice, few spacers exist in the mobility range of proteins, the positions of which relative to specific proteins could be convenlently located on the basis of isotope analysis or other assays. Mixtures of multiple spacers with undefined mobilities appear applicable as “blind spacers” only at concentrations so low that their effectiveness is annulled.     

Clinical applications of capillary electrophoresis

Capillary electrophoresis (CE) is an extremely sensitive technique, which has been used in the clinical laboratory for almost 10 yr. The components of CE instrumentation are described, as are injection modes, buffers, and effects of electroosmotic flow. The modes of separation used in CE, namely, capillary zone electrophoresis, capillary isoelectric focusing, capillary isotachophoresis, and micellar electrokinetic capillary chromatography, are explained. References for 26 different clinical applications of CE are included, among them assays that are used routinely as well as niche assays for specialized applications of CE. Verification of CE assays, current instrumentation, and future development of CE in the clinical laboratory are addressed.     

Studies on pig serum lipoproteins. VI. Surface charge of very low density lipoprotein.

The surface electric charge of pig serum very low density lipoprotein (VLDL) is described. By isoelectric focusing VLDL was separated into at least 3 fractions having different isoelectric points and polypeptide distributions. The ultracentrifugal and electron microscopic results indicate that the VLDL was not drastically denatured by Ampholine.     

Isotachophoretic determination of urinary citrate in native urine

The technique of isotachophoresis has been used to develop a specific and sensitive method for the determination of citrate in unprocessed urine. The specificity of the isotachophoretic method was assessed using citrate lyase which caused disappearance of the isotachophoretic citrate signal. The isotachophoretic method compared favourably with the enzymatic method (citrate lyase) for urinary citrate. The normal range for urinary citrate in 25 healthy individuals, as found by isotachophoresis, was 0.33–2.89 mmol/24 h with a mean of 2.1 mmol/24 h.     

Studies on camel semen. II. Biochemical characteristics

The mean concentrations of fructose, citric acid, total proteins and lipids in the seminal plasma of camel were 23.5±2.5, 9.8±2.9, 775±15 and 87±32 mg/ml respectively. The corpus prostatae seemed to be the principal source of fructose and citric acid, smaller amounts are contributed by the bulbourethral glands, ampulla ductus deferentis and pars disseminata of the prostate. Electrophoretic fractionation of seminal plasma proteins by capillary isotachophoresis revealed eight protein bands similar to those of blood serum. Electrofocusing in polyacrylamide gels on the other hand showed the presence of eighteen fractions with minor variations from fractions obtained from blood serum.     

Preparative isoelectric focusing of human serum very low-density and low-density lipoproteins.

Ten percent glycerol prevented the usual precipitation of human serum very low-density lipoproteins (VLDL) and low-density lipoproteins (LDL) at their isoelectric points during their preparative isoelectric focusing (IEF), IEF separated VLDL and LDL into two major fractions. The observed optical density peaks are not artifacts caused by binding of Ampholines to VLDL or LDL since no radioactivity accumulated in the fractions containing VLDL or LDL during IEF in the presence of [¹⁴C]Ampholine, and gel filtration completely separated the lipoproteins from [¹⁴C]Ampholine. These results suggest that IEF may separate subspecies of VLDL and LDL under suitable experimental conditions.     

Two-dimensional electrophoresis on the layers of cellulose acetate membrane

A new type of two-dimensional electrophoresis for analysis of protein using cellulose acetate membrane has been developed. Prior to the separation, proteins in a sample are concentrated to a narrow zone on a strip of cellulose acetate according to “steady-state stacking” of isotachophoresis. Electroendosmotic counterflow on cellulose acetate membranes is advantageous for the isotachophoretic concentration of large sample volumes. The concentrated protein zone is then subjected to electrophoretic separation on the same strip. This first-dimensional separation including the concentrating process is named “concentrating electrophoresis.” Iso-electric focusing on several layers of cellulose acetate membrane is performed in the second-dimensional step. Many kinds of detection methods can be applied to the layers among which proteins are distributed. The novel two-dimensional electrophoresis takes only 5 h to perform.     

Isotachophoretic electrodesorption of proteins from an affinity adsorbent on a microscale

Cationic isotachophoresis was used for the desorption of mouse monoclonal antibody to transferrin strongly affinity-bonded to transferrin immobilized on polyethyleneglycol terephthalate powder. The electrodesorption under nondestructive conditions was effected in the capillary isotachophoresis apparatus of our own construction which was equipped with an adsorption element. The electrodesorption is on-line connected with quantitative isotachophoretic analysis of the antibody desorbed. Only a few tens of microliters of the affinity adsorbent and several nanomoles of the antibody are needed for the characterization of the capacity of the affinity adsorbent and the conditions of adsorption and desorption.     

Isolation of a hibernation inducing trigger(s) from the plasma of hibernating woodchucks

Plasma from hibernating woodchucks was desalted utilizing a hollow fiber device having a M. W. cut-off of 5,000. This preparation was fractionated by isoelectric focusing (IEF) in a pH gradient extending from 3.5 to 10.0 resulting in protein components having isoelectric points (pIs) of 4.5, 5.2, 5.5, 6.3, and 7.0. Fraction I (comprised of proteins having pIs of 4.5 and 5.2) induced hibernation within 2 to 6 days in 8 out of 10 summer-active ground squirrels. Fraction II (pI 5.5) and Fraction III (pI 6.3 and 7.0) failed to induce any summer hibernation in 10 animal test groups at identical sample concentrations. Polyacrylamide gel electrophoresis of Fraction I indicated that albumin was a major constituent of this still heterogeneous preparation. Thus, in order to more clearly define the plasma locus of this hibernation inducing trigger(s) (HIT) molecule, whole plasma and/or Fraction I was fractionated by 3 distinct resolving techniques. These included sub-fractionation of Fraction I by isoelectric focusing utilizing a narrower pH gradient extending from 3.5 to 6.0, isotachophoresis of whole plasma and affinity chromatography of Fraction I and whole plasma. A total of 40 summer-active ground squirrels were injected and assayed for HIT activity with fractionated preparations derived by the three previously cited separation techniques. A total of 18 of these summer-active ground squirrels hibernated. However, a much more impressive figure is that 16 out of 21 animals hibernated when injected with resolved hibernating plasma fractions in which albumin was the predominant plasma protein. A total of 8 control animals were injected with vehicle and none of these hibernated.     

Scanning isoelectric focusing in small density-gradient columns: I. Use of a Standard Spectrophotometer Cuvette for Focusing. Chemical Modification of Proteins by Migrating Reactive Ions

By the method of isoelectric focusing in a sucrose density gradient, small protein samples (less than 100 μg) have been separated and analyzed within 2 hr, using as electrolysis column a commercial standard quartz spectrophotometer cuvette, equipped with platinum electrodes and placed in an optical scanning device. Preparation of the cuvette prior to an isoelectric focusing experiment required about half an hour with no external apparatus, as the density gradient was created spontaneously in the cell by free interdiffusion of sucrose solutions. The cuvette temperature could be controlled by circulating water. The optical detection device permitted repeated scanning of the cuvette during the electrolysis process, thus providing information about the events occurring to a protein during focusing or prolonged electrolysis. By scanning with wavelength at the positions where the proteins have focused, their absorption spectra were obtained. the isoelectric points of separated proteins were estimated by fractionation of the cell contents and subsequent pH measurements on the fractions.The present paper also describes how individual Ampholine components, or groups of components, in their focused states gave rise to easily detected refractive-index gradients within the cell. The optical scanning device has been built in such a way that interference of these gradients with absorption measurements was abolished.Application of the technique to the isoelectric separation of commercial sperm whale myoglobin is reported. Ferrous or ferric forms of the focused myoglobin components were obtained by migration of reducing or oxidizing agents through the zones.     

Heterogeneity in horse ferritins. A comparative study of surface charge, iron content and kinetics of iron uptake.

Horse ferritins from different organs show heterogeneity on electrofocusing in Ampholine gradients. Both ferritin and apoferritin from liver and spleen could be fractionated with respect to surface charge by serial precipitation with (NH4)2SO4. In the ferritin fractions, increasing iron content parallels increasing isoelectric point. After removal of their iron, those fractions which originally contained most iron accumulated added iron at the fastest rates. When unfractionated ferritins from different organs were compared the average isoelectric point increased in order spleen less than liver less than kidney less than heart. The order of initial rates of iron uptake by the apoferritins was spleen greater than kidney greater than heart and initial average iron contents also followed this order. The relatively low rates of iron accumulation by iron-poor molecules may have been due to structural alteration, to degradation, to activation of the iron-rich molecules or to other factors.     

Binding of ampholine to transfer RNA.

The melting temperature of isoaccepting tRNAfMet is affected by Ampholine. The plot of Tm versus the logarithm of Ampholine concentration shows clearly an increasing effect of Ampholine when the pH changes from 7.4 to 4.2. This result is interpreted as binding of Ampholine to the nucleic acid. The effects of Ampholine have been compared with those of soidum, magnesium and tetraethylene pentamine. Ampholine carrier ampholytes at pH 4.2 bind to tRNA with the same affinity as magnesium; at higher pH values they are less active. An hypothesis for the mechanism of action of Ampholine on nucleic acids during isoelectric focusing is proposed.     

Evaluation of extractants for soil humic substances

Summary An evaluation of alkaline extractants was done by isotachophoresis and compared with infrared, ultraviolet and visible spectroscopic analysis. The electrophoretograms show that the humic acid extracted. This result is partially corroborated by the E₄/E₆ ratio. Differences in the carboxyl content and TRIS. In the pyrophosphate humic acid three fractions of high molecular weight were not extracted. This resultis partially corroborated by the E₄/E₆ ratio. Differences in the carboxyl content found by ir spectra of the TRIS humic acid and the NaOH humic acid were not shown in the isotachophoretic separation.     

Isolation of a Hibernation Inducing Trigger(s) From the Plasma of Hibernating Woodchucks

Plasma from hibernating woodchucks was desalted utilizing a hollow fiber device having a M. W. cut-off of 5, 000. This preparation was fractionated by isoelectric focusing (IEF) in a pH gradient extending from 3. 5 to 10. 0 resulting in protein components having isoelectric points (pis) of 4. 5, 5. 2, 5. 5, 6. 3, and 7. O. Fraction I (comprised of proteins having pis of 4. 5 and 5. 2) induced hibernation within 2 to 6 days in 8 out of 10 summer-active ground squirrels. Fraction II (pI 5. 5) and Fraction III (pi 6. 3 and 7. 0) failed to induce any summer hibernation in 10 animal test groups at identical sample concentrations. Polyacrylamide gel electrophoresis of Fraction I indicated that albumin was a major constituent of this still heterogeneous preparation.

Thus, in order to more clearly define the plasma locus of this hibernation inducing trigger(s) (HIT) molecule, whole plasma and/or Fraction I was fractionated by 3 distinct resolving techniques. These included sub-fractionation of Fraction I by isoelectric focusing utilizing a narrower pH gradient extending from 3. 5 to 6. 0, isotachophoresis of whole plasma and affinity chromatography of Fraction I and whole plasma. A total of 40 summer-active ground squirrels were injected and assayed for HIT activity with fractionated preparations derived by the three previously cited separation techniques. A total of 18 of these summer-active ground squirrels hibernated. However, a much more impressive figure is that 16 out of 21 animals hibernated when Injected with resolved hibernating plasma fractions in which albumin was the predominant plasma protein. A total of 8 control animals were injected with vehicle and none of these hibernated.     

Isoelectric focusing in continuous-flow electrophoresis. I. Separation of mixed red blood cells of different species.

A noncommercial continuous-flow isoelectric focusing (CIF) apparatus which was formerly applied to separate mixtures of proteins was used to study the separation of red blood cells (RBC's) of different species. A mixture of human, mouse and rabbit erythrocytes, a good model for demonstration of cell separation by CIF, was completely separated into the three components. The separation was performed by isoelectric focusing in pH gradients, 3–10 and 5–7, using Ampholine carrier ampholytes at a field strength of 110 V/cm and a flow-through time of RBC's of 7 min. The isoionic points of human RBC's both determined by CIF and calculated from electrophoretic mobility measurements by extrapolation to zero electrophoretic mobility and zero ionic strength were found at pH 5.6–5.7. The method of CIF which is presently used to isolate a pure lysosomal fraction seems to be a valuable method for the separation of mixtures of cells or cell organelles.